Complexes Having - American Chemical Society

Mark S. Wrighton,*' Harmon B. Abrahamson, and David L. Morse. Contribution from the Department of Chemistry, Massachusetts Institute of. Technology ...
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Photosubstitution Reactivity of a Series of Pentacarbonylpyridinotungsten(0) Complexes Having Ligand Field or Charge-Transfer Lowest Excited States Mark S. Wrighton,*’ Harmon B. Abrahamson, and David L. Morse Contributionfrom the Department of Chemistry, Massachusetts Institute of Technology, Cambridge, Massachusetts 02139. Receioed August 21, I975

Abstract: Emission, electronic absorption, and photosubstitution efficiencies are reported for W(C0)sX ( X = 3,4-dimethylpyridine, 4-methylpyridine, pyridine, 3-bromopyridine, 3-acetylpyridine, 3-benzoylpyridine, 3,5-dibromopyridineq4-cyanopyridine, 4-acetylpyridine, 4-benzoylpyridine, and 4-formylpyridine). The spectral data show that the W pyridyl charge transfer (CT) state moves smoothly to the red with more electron-withdrawing substituents. Using W(CO)s(piperidine) as a comparison, the ligand field (LF) absorptions remain constant in energy for all X used here. Photosubstitution of X occurs in all cases upon irradiation into the lowest energy absorption system, but the quantum efficiency is a dramatic function of whether the lowest energy absorption is LF or W X CT. The CT state is virtually unreactive [W(C0)5(4-formylpyridine) yields substitution of 4-formylpyridine at 514 nm with a quantum efficiency of 0.0021, while the LF state gives X substitution with a quantum efficiency of -0.60 for complexes where the LF state is the lowest energy excited state.

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The aim of this paper is to report the results of an investigation of the absorption and emission spectroscopy and photosubstitution reactivity of W(CO)5X, where X is a substituted pyridine. W e have attempted to vary the nature of the lowest electronic excited state in W(CO)5X by simple variation in the substituents on pyridine, in order to gain insight into the substitution reactivity of certain types of electronic states in a situation where the essential components of the coordination sphere are constant. Quite a great deal of work has already been undertaken toward understanding the photochemistry and spectroscopy of metal carbonyls2 and particularly of W ( C 0 ) s X complexes. For X = n-electron donor, the lowest absorption bands were assigned3 as ligand field (LF) IAl(e4bl2) 1-3E(e3b22al’). and it was f o ~ n d that ~ - ~emission from the 3E state occurs a t low temperatures. Photosubstitution of both X and C O are found in W(CO)5Xs-8 in solution a t room temperature. The dominant reaction is efficient dissociation of X for X = pyridine or aliphatic amine when the irradiation is into the lowest L F absorption band s y ~ t e m .The ~ . ~quantum efficiency for W-X dissociation is generally 1 0 . 5 for the cases investigated,5.6 and though the efficiency for CO substitution increases with increasing excitation energy the dominant reaction remains loss of X, which is consistent with a substantial amount of reaction from the lowest excited state even when upper excited states are directly populated. Dissociative loss of X is consistent with the directed a-antibonding nature of the dz2 orbital, which is populated in the lowest L F excited states. For X = pyridine, but not aliphatic amine, one expects a relatively low lying W X charge-transfer (CT) absorption because the complex is low valent and there are accessible T* pyridine levels. Such a transition has not been identified in the absorption spectrum of W(CO)s(py) (py = pyridine), but we have recently encountered spectral differences in W(CO)s(pip) (pip = piperidine) and W(CO)5(py), which point to the presence of such a transition to the blue of the lowest L F absorption system. With variation in the substituents on pyridine the W pyridine CT should vary in energy. Complexes Ru(NH3)5X2+ (X = substituted pyridine) are also C4L,low-spin d6 systems having low lying Ru X CT.9 The position of the Ru X CT absorption band in H2O varies from 398 nm for X = 4-methylpyridine to 545 nm for X = 4-formyl~yridine.~ The photochemistry of R U ( N H ~ ) ~ (in~ HzO ~ ) ~ has + been investigated for irradiations corresponding to Ru pyridine CT.’OBoth NH3 and pyridine are photoaquated with modest quantum efficiency. There is little selectivity for substitution

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Wrighton, Abrahamson, Morse

of cis- or trans-NH3 or the pyridine, and one might be thus tempted to ascribe the reactivity to some LF character of the lowest excited state. Since the R ~ ( N H 3 ) 5 ( p y ) ~complex + has essentially an Oh field, it is appropriate to consider the lowest L F state to be nearly the same as in R ~ ( e n ) 3 ~(en + = ethylenediamine), which has no low-lying CT absorption. The L F ‘ A I ~ ( ~ Q ~‘Tlg(t2g5egi) ) transition in R ~ ( e n ) 3 ~falls + at 370 nm (6 40 I. mol-] cm-l),li which is comparable energetically to the position of the R u pyridine C T absorption inR u ( N H 3 ) ~ ( p y ) ~(407 + ~ nm, t 7762 I. mol-’ cm-I). Accepting the notion that the Ru pyridine CT state can be viewed as a Ru(II1) complex of the radical anion of pyridine, there is no compelling reason to expect such a state to have vastly enhanced substitution rates. Given that the excited state lifetimes are very short (likely less than s), it is likely that the excited states responsible for substitution must have substitution rate constants which are perhaps 10 to 20 orders of magnitude larger than those for the ground electronic state. The thermal substitution stability of both Ru(I1) and Ru(II1) amine complexesi2 is seemingly inconsistent with a strong labilization from a R u pyridine C T state. By way of contrast, the L F states should be strongly 1abili~ing.I~ Recently, convincing evidence has been reportedI4 showing that the Ru pyridine C T state is not likely the substitutionally reactive state. The convincing result14 is that complexes of substituted pyridine having very low energy CT absorption, such as Ru(NH3)5(4-formyl-py)*+, have very inefficient photosubstitution processes. These results are consistent with a reactive L F state. Among metal carbonyls, the only mononuclear complexes which have been investigated which unequivocally have a M ligand C T lowest excited state are W(C0)dL (L = 1.10phenanthroline and related ligands).15 For these complexes the W L C T transition yielded no detectable C O substitution, though direct absorption into upper excited states ( L F ? ) yielded modest C O dissociation quantum yields. In substitution-inert metal carbonyls, the M L CT states might yield substitution lability with respect to CO dissociation due to the “oxidation” by one unit of the central metal, since stable C O complexes are generally found for the lower oxidation state metals. Similar reasoningI6 leads to the conclusion that the a-donor ligands will tend to be more substitutionally inert in the higher oxidation state.

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Results and Discussion a. Synthesis of W(C0)sX. Preparation of W ( C 0 ) s X was by

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Photosubstitution Reactivity of W(CO)5(py)Complexes

4106 Table I. Carbonyl Infrared Stretching Bands for W ( C 0 ) s X

X

Bands, cm-' 2070 (w) 2071 (w) 2071 (w) 2072 (w) 2073 (w) 2070 (w) 2071 (w) 2071 (w) 2071 (w) 2071 (w) 2071 (w) 2072 (w)

3,4-Dimethylpyridine 4-Methylpyridine Pyridine 3-Bromopyridine 3.5-Di bromopyridine Piperidine 4-acetyl pyridine 4-Benzoylpyridine 4-Cyanopyridine 4- Formylpyridine 3-Benzoylpyridine 3-Acetylpyridine

1914 (m) 1917 (m) 1918 (m) 1923 (sh) 1927 (sh) 1915 (m) 1923 (sh) 1921 (sh) 1927 (sh) 1927 (sh) 1920 (sh) 1921 (sh)

1928 (s) 1929 (s) 1930 ( s ) 1932 (s) 1933 (s) 1926 (s) 1932 (s) 1930 (s) 1931 (s) 1935 (s) 1928 (s) 1930 (s)

298 K in isooctane; (w) = weak; (m) = medium; (s) = strong; and ( s h ) = shoulder.

3

Figure 2. Absorption spectra at 298 K in isooctane (-) and isooctane/ EtOH ( 1 : l volume) (- - -) for W(C0)sX at the same concentration for both solvents. A = W(C0)~(3,4-diMe-py);B = W(CO)s(4-Me-py); C = W(CO)s(py); D = W(CO)s(3-Br-py); E = W(CO)s(3,5-diBr-py); F = W(CO)s(4-acetyl-py); G = W(CO)s(pip).

.Noie1erg,t

"r.

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1 1

Figure 1. Comparison of temperature and solvent effects on absorption of W(CO)s(pip) and W(CO)5(pyl. Curves A and C are for the piperidine complex and curves B and D are for the pyridine complex. For A and B the solvent is I-pentene and the solid curve is the spectrum at 298 K and the dashed curve is at 77 K (uncorrected for solvent correction). Curves C and D are for 298 K spectra in isooctane (-) and at the same concentration isooctane/EtOH ( 1 : l by volume) (- - -).

W(CO),

hu 7 W(CO,,X + co

W(CO1,

(1)

N. purge

1

(piperidinel

04

4

isooctane

solvent

W(CO),

hv

W'(CO),THF

+

x A

W(CO),X

+

THF ( 2 )

350

400

4

L

O

b

550

660

W a v e l e n g t h . nm

co one of the two routes indicated in the reactions 1 or 2. Both routes have considerable p r e c e d e n ~ e , ~ even . ~ ' though only a few of the W(CO)5X complexes studied have actually been reported. Usually, the major impurity (aside from unreacted starting materials) from the synthetic procedures used is W(CO;)4X2. Generally, purification can be achieved by chromatography on alumina. Ir band maxima (Table I) for the W(CO)5X complexes are consistent with the CdLarrangement of the five CO's, and, importantly, the similarity of all the complexes is consistent with bonding of the pyridine through the pyridine ring nitrogen atom. Specifically, the 4-cyanopyridine complex is likely bound through the pyridine nitrogen atom based on both the position of the CEN stretch of the complex (2236 cm-') compared to the free ligand (2236 cm-l) Journal of the American Chemical Society

O'O&k

Figure 3. Comparison of the absorption spectra of W(CO)s(pip) and W(CO)s(4-formyl-py) at 298 K in isooctane. Note that all of the bands present in W(tO)s(pip) are present in W(CO)s(4-formyI-py) at very nearly the same position and relative intensity.

and the similarity of the CO stretching bands to those for the pyridine complex. b. Electronic Absorption Spectra. Electronic spectra for the W(CO)5X complexes have been recorded in solution. Some spectra are shown in Figures 1-3 and data are summarized in Table 11. First, spectra of W(CO)s(py) and W(CO)s(pip) are compared in Figure 1. Each complex exhibits a low energy band near 440 nm ( t 500 1. mol-' cm-I), which is the one previously associated2-6 with the L F l A 1 ( e ~ b 2 ~ ) 3E(e3bz2al') transition. The corresponding singlet-singlet L F

/ 98.14 / July 7, 1976

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4107 Table 11. Spectral Band Maxima and Assignments for W ( C 0 ) s X Complexeso

Abs. max, nm ( c ) ~

Xb

Piperidine 3,4-DiMe-py 4-Me-py PY 3-Br-py 3-Acetyl-py 3-Benzoyl-py 3,5-DiBr-py 4-Benzoyl-py 4-Acetyl-py 4-CN-py 4-Formyl-py

443 435 437 440

407 (3960) 347 (6580) 351 (6960), 375 (6730) 382 (7480) 399 (9670) 398 (7550) 400 (5700) 407 (9410) 405 (7410), 435 (6600) 404 (8400), 440 (8200) 404 (5530), 455 (7060) 402 (5300), 470 (6470)

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(560) (61 5) (655) (61 5)

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'Al(e4bz2) 'E(e3bzzalI), nm ( e )

f f f -445

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transition is associated with the absorption band near 400 nm (e 5000-7000 I. mol-' cm-l). In the region near 340 nm (in 1 :1, isooctane/EtOH, v/v) the W(CO)s(py) has an absorption band which is apparently not present in the W(CO)5(pip). Moreover, the position of this band is extraordinarily sensitive to the solvent compared to the 440 or 400 nm band in either the pyridine or piperidine complex. The band appears to blue shift in more polar media just as does the W phenanthroline CT band in W(CO)4(phen)l8 (phen = 1,lO-phenanthroline). The band is clearly present in the 77 K spectrum of W(CO)s(py), but not in W(CO)s(pip). These results are enough for us to tentatively ascribe the 340 nm band in W(CO)s(py) to a W pyridine C T transition. In Figure 2 and Table I1 spectroscopic data are given for several complexes of various substituted pyridines. Generally, the more electron-withdrawing substituent yields a lower energy W X C T absorption. But it is not until one gets to the 4-acetyl, 4-cyano, 4-benzoy1, and 4-formyl derivatives that the CT band moves markedly below the L F ' A I 1,3Ebands. The shift of the W X CT band in isooctane is 6600 cm-' from X = 4methylpyridine to 4-acetylpyridine, and this is quite comparable to the shift of the Ru X CT in Ru(NH3)5X2+ for the same two X's.I4 The solvent effect on the W X CT is uniformly a large blue shift with the more polar medium. Importantly, from the 4-substituted pyridines with strongly electron-withdrawing substituents we see that the band a t 400 nm, ascribed to the 'A, IE L F absorption, is still present as a prominent feature of the spectrum. A remarkable comparison of W(CO)s(pip) and W(CO)s(4-formyl-py) is shown in Figure 3, which clearly reveals that all of the bands present in the piperidine complex are present in the 4-formylpyridine complex a t nearly the same energies. We thus feel the state diagrams indicated in Scheme I are appropriate in absorption. The data

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W-XCT, nm ( e )

407 (3960) -390 -390 -390 Overlapping C T and L F e Overlapping C T and L F e Overlapping C T and LFr Overlapping C T and LF' 405 (7410) 404 (8400) 404 (5530) 402 (5300)

Isooctane solutions a t 298 K . py = pyridine. Only actual band maxima are given here. For example, cf. curves D and E in Figure 2. /Obscured by W X CT absorption. (I

e

lAl(e4bz2) )E(e3bzzai nm (6)

None 347 (6580) 351 (6960) 355 (-6800)

435 (6600) 440 (8200) 455 (7060) 470 (6470)

Generally, this band is only a shoulder.

Table 111. Emission Data for W ( C 0 ) s X in EPA a t 77 K

X 3,4-Dimethylpyridine 4-Methylpyridine Pyridine 3-Bromopyridine 3-acetyl pyridine 3-benzoyl pyridine 3.5-Di bromopyridine 4-Cyanopyridine 4-Acetylpyridine 4-benzoyl pyridine 4-Formylpyridine Piperidine

Emission max,'

Emission halfwidth,b

kK

kK

19.7 19.6 19.1 18.9 18.7 18.5 18.1 16.6 17.0 16.8 15.2 18.3

3.1 3.1 4.0 4.1 4.4 4.4 2.9 4.1 4.5 4.2 4.0 4.1

Emission lifetime x 106 0.96 1.07 0.86

1 .oo

1.17 1.25 1.25 33.0 38.3 29.5 15.0 0.82

Corrected for variation in detector response as a function of wavelength. Width of emission band at half-height.

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show, beyond reasonable doubt, that in absorption the position of the W X C T can be changed rather dramatically by tampering with the electronic nature of X, while the L F absorptions are essentially not affected. The L F bands are unobservably weak in Ru(NH3)5X2+, but it was assumed that they are not shifted by changes in the various pyridines, X.I4 The invariance of the bands a t -400 nm is consistent with their L F character in that the changes in the CT properties have been brought about without changing the set of donor atoms coordinated to the central metal. Similarly, the L F bands present in W(C0)4(en)19 are present in about the same position in W(CO)4(phen),l9 which has W 1,lO-phenanthroline CT at lower energy. W e outline below results on radiative decay and photosubstitution of X in W ( C 0 ) s X which show that the state diagrams shown in Scheme I are still appropriate for the relaxed excited states. c. Emission of W(C0kX. All of the W ( C 0 ) s X complexes investigated here undergo radiative decay subsequent to electronic excitation at 77 K in EPA solution. Corrected emission spectra have been measured for all of the complexes. The corrected emission maximum, the width of the emission peak a t half-height, and the emission lifetimes for all of the complexes are listed in Table 111 and corrected spectra are shown for several complexes in Figure 4. The spectral distribution and efficiency of the emission are insensitive to the excitation wavelengths longer than 300 nm. Several points are

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/ Photosubstitution Reactivity of Wo(CO),(py)Complexes

4108 Table IV. Photosubstitution of X in W(CO)sXa Lowest excited state

O f 10% X

436nm

3,4-Dimethylpyridine 4-Methylpyridine Pyridine 3-Bromopyridine 3-Acetylpyridine 3-benzoyl pyridine 3,5-Dibromopyridine 4-Benzoylpyridine 4-Cyanopyridine 4-Acetylpyridine 4-Formylpyridine PiDeridine

0.53 0.55 0.62 0.66 0.75 0.73 0.82 0.12 0.12 0.15 0.05 0.58

514nmb

LF LF LF LF LF LF LF W-XCT W-XCT W-XCT W-XCT LF

0.02 0.02 0.02 0.002

a Irradiation carried out at 298 K in isooctane/l-pentene (2/1 by volume). The only photoproduct is W(CO)s(l-pentene). Data at 514 nm are given only for those complexes that absorb sufficiently to give accurate quantum yields.

\c

idine likely reflects an increasing admixture of C T character to the lowest excited state as the emitting C T and LF states become closer energetically, and finally the CT crosses below the L F level for the 4-Y-pyridines for Y = cyano, acetyl, benzoyl, and formyl. d. Photosubstitution of X in W(C0)sX. Photoinduced substitution of X occurs in W ( C 0 ) s X upon excitation into the lowest energy absorption. W e have investigated the quantum efficiency for the reaction W(C0)sX

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436 nm

W(CO)s(l-pentene)

I-pentene

+X

(3)

under a constant set of conditions. In all cases, the reaction is essentially quantitative with little contribution from reaction 4 (4 I O . 0 1 ) . W(C0)sX

436 nm

* W(CO)4(X)(l-pentene) + CO

(4)

I-pentene

Quantum yields determined for reaction 3‘are summarized in Table IV, and typical electronic absorption spectral changes accompanying the reaction are depicted in Figure 5 for W(C0)~(3,4-diMe-py)and W(CO)s(4-formyl-py). Quantum yields for several complexes are also shown for 514-nm photolysis. The data show that for the complexes where a W X C T absorption is the lowest energy absorption, there is a relatively low quantum yield for substitution. The complexes showing low substitution quantum yields are just those which show the lowest energy emission and have the longest emission lifetimes. It is unlikely that the differences in substitution yields are due to the “bulk” of the substituent, since for X = 3-benzoylpyridine or 3-acetylpyridine quantum yields typical of a LF lowest excited state are obtained, consistent with the absorption and emission data. Therefore, we conclude that the W X CT state is unequivocally and significantly less reactive than the lowest LF states with respect to substitution of X . This conclusion is in accord with that for Ru(NH3)sX2+.I4 Aside from our conclusion that the W X CT state is relatively unreactive with respect to dissociative loss of X, we can comment intelligently on the consequences of W ligand CT with respect to loss of CO. Obviously, the complexes studied here do not undergo efficient dissociative loss of C O from the lowest excited state. Consequently, we must conclude that depopulation of r - d orbitals, which are x bonding with respect to the W-CO interaction, does not labilize C O to an extent which allows dissociation within the lifetime of the excited state. This obtains despite the fact that the W X C T tran-

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14

1 6

18

energy, kK

20

22

Figure 4. Corrected emission spectra in EPA at 77 K for W(C0)sX. A-G are the same as in Figure 2. The excitation wavelength is 351, 364 nm.

worth noting. First, there appears to be a sharp break in emission lifetimes from -1 to 15-30 p s for complexes having L F and C T lowest energy absorptions, respectively. Second, while there is a general trend to lower energy emission maxima with increasing electron-withdrawing power of X, there is a sharp decline in emission energy for those complexes having lowest W X CT absorptions. The general decline in emission energy with a more electron-withdrawing substituent on pyr-

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Journal of the American Chemical Society

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/ 98:14 / July 7 , 1976

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4109 0

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9

7

t 0.6n i

0.5C

3 0.4F

k 0.30.2 -

0.1 L

h

0.I 1

300

1

,

I

400 500 WAVELENGTH, nm

Figure 5. Electronic absorption spectral changes accompanying the 436 nm irradiation of A, W(C0)5(3,4-diMe-py) and B, W(CO)5(4-formyl-py) in isooctane/l-pentene (2:l by volume) at 298 K. The photoproduct in each case is W(CO)s(l-pentene).

sition can be viewed as a central metal oxidation which should a priori labilize the W-CO bond. Our results here argue against the possibility of an M CO C T reactive state in M(CO)6 (M = Cr, Mo, W). The notion5 that the reactive excited states are just those of the L F t2g eg type remains secure. Differences in the 5 14-nm and the 436-nm quantum yields deserve some comment. For the complexes where 514-nm irradiations are possible the W X CT state gives rise to the lowest energy absorption band. When the lowest absorption band corresponds to the L F 'A 3E or to a mixture of the L F and CT transitions, the molar absorptivity is not great enough a t 5 14 nm to allow accurate determinations of photosubstitution efficiency. The differences that do obtain likely reflect the fact that the L F state can yield substitution a t a rate which is very competitive with internal conversion to the lowest CT state. Similarly, strongly wavelength-dependent C O photosubstitution was found in W(CO)d(phen) and related complexes where a W 1,lO-phenanthroline CT transition is lowest in energy.I5 Experimental Section

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Materials. All substituted pyridines and solvents used are commercially available and were used without purification. Tungsten carbonyl was obtained from Pressure Chemical Co. The isooctane used was spectroscopic grade, and the I-pentene was obtained from Chemical Samples Co. (>99% pure). Synthesis of W(C0)sX (X = Pyridine or Substituted Pyridine). Preparation of W ( C 0 ) s X was either (1) by irradiation of W(CO)6 in the presence of X in N2 purged isooctane solution or (2) by thermally reacting photogenerated W(CO)s(THF) with X in N2 purged T H F solution. In either case the W ( C 0 ) s X was recovered by first evaporating the solvent followed by chromatography on alumina. Elution first with isooctane removed W(CO)6 and elution with Et20 typically moved the W(C0)sX. The Et20 was then removed by rotary evaporation. Purity was established spectroscopically. In all cases photosubstitution of X by I-pentene yielded W(CO)s(l-pentene) in the correct stoichiometric amount consistent with the fact that all W(CO)5X were pure. Typically, the major difficulty in purity was the presence of free ligand. In some cases, repeated chromatography

Wrighton, Abrahamson, Morse

was required to achieve pure W(CO)5X. The synthetic procedures are well e ~ t a b l i s h e d . ~ * ~ ~ " Spectra. Infrared spectra were recorded using a Perkin-Elmer Model 521 spectrometer. Uv-vis absorption spectra were obtained with a Cary 17 spectrophotometer. Low-temperature absorption spectra were obtained using an all quartz liquid N2 Dewar fitted with optical quality quartz flats for windows. Emission spectra were typically obtained using the detection optics of the Cary 17. The sample was placed at the source position of the Cary 17 and the emission was excited with an argon ion laser tuned to the 35 1, 364 nm doublet. The maximum power of the Spectra Physics Model 164 laser operated in this manner was approximately 20 mW. The emission spectra were constant in time, evidencing no photoreaction by the excitation light. A 77 K Dewar, typically used with an Aminco-Bowman emission spectrophotofluorometer, was used for the Cary 17 emission studies. Emission spectra were corrected using the procedure and equipment described previously.20 Excitation spectra for the emission were obtained using an Aminco-Bowman SPF-2 spectrophotofluorometer. Emission lifetimes were determined using the procedures and equipment described previously.20 Since there existed the possibility of multiple emissions (LF and CT), we were careful to look for nonexponential plots of log (emission intensity) vs. time. No evidence for multiple emissions was obtained at 77 K in EPA solutions. Irradiation Procedures. All irradiations were carried out using merry-go-rounds to expose 3.0-ml aliquots of W ( C 0 ) s X in isooctane/l-pentene (2:l by volume) in hermetically sealed 13 X 100 mm Pyrex test tubes. The solutions were typically degassed by three freeze-pump-thaw cycles prior to being sealed. The 436-nm irradiations were carried out using a Hanovia 450-W medium pressure Hg lamp filtered with Corning glass filters to isolate the 436 nm emission. Irradiations at 5 14 nm were carried out using the argon ion laser with a 6X beam expander. Light intensity was determined by ferrioxalate actinometry2' (436 nm) or Reinecke's salt actinometry22 (514 nm). The photoproduct of W(C0)sX is W(CO)s(l-pentene) by ir (2080(w), 1965(s), 1952(s) cm-I) and uv-vis spectra. The large difference in the absorption spectra of W ( C 0 ) s X and W(CO)s(Ipentene) allowed quantitative determination of the extent of reaction by measuring the optical density as a function of irradiation time; cf. Figure 5 .

Acknowledgment. W e thank the National Science Foundation for support of this research. References and Notes (1) Fellow of The Alfred P. Sloan Foundation, 1974-1976, and recipient of a Dreyfus Teacher-Scholar Grant, 1975-1980. (2) M. Wrighton, Chem. Rev., 74, 401 (1974). (3) M. Wrighton, G. S. Hammond, and H. B. Gray, J. Am. Chem. SOC.,93,4336 (1971) , ,. M. Wrighton, G. S. Hammond. and H. B. Gray. lnorg. Chem., 11, 3122 (1972). M. Wrighton, G. S. Hammond. and H. 6. Gray, Mol. Photochem., 5, 179 (1973). M. Wrighton, lnorg. Chem., 13, 905 (1974). (a) W. Strohmeier and D. von Hobe, Chem. Ber., 94, 2031 (1961); (b) W. Strohmeier and D. von Hobe, 2. Phys. Chem. (Frankfurtam Main), 34,393 (1962). G . Schwenzer, M. Y. Darensbourg. and D. J. Darensbourg, Inorg. Chem., 11, 1967 (1972). P. Ford, De F. P. Rudd, R. Gaunder. and H, Taube, J. Am. Chem. SOC..90, 1187(1968). (a) D. A. Chaisson, R. E. Hintre, D. H. Stuermer. J. D. Pedersen, D. P. McDonald, and P. C. Ford, J. Am. Chem SOC.,94, 6665 (1972); (b) P. C. Ford, D. H. Stuermer, and D. P. McDonald, J. Am. Chem. SOC., 91, 6209 (1969): (c) P. C. Ford, D. A. Chaisson, and D. H. Stuermer, Chem. Commun., 530 (1971). A. B. P. Lever, "Inorganic Electronic Spectroscopy", Elsevier, New York, N.Y., 1968, p 302. (a) F. Basolo and R . G. Pearson, "Mechanisms of Inorganic Reactions", 2d ed., Wiley. New York, N.Y. 1967; (b) H. Taube, Surv. Prog. Chem., 6, 1 (1973); (c) P. C. Ford, Coord. Chem. Rev.. 5, 75 (1970). M. Wrighton, H. B. Gray, and G. S. Hammond, Mol. Photochem., 5 , 165 (1973). G. Malouf and P. C. Ford, J. Am. Chem. SOC., 96, 601 (1974). M. S. Wrighton and D. L. Morse, J. Organomer. Chem., 97, 405 (1975). These considerationscould just as well be couched in terms of "hard" and "soft" arguments. W. Strohmeier, Anaew. Chem., 76, 873 (1964). (18) H. Saito, J. Fujita, and K. Saito, Bull. Chem. SOC.Jpn., 41, 863 (1968). (19) H. Saito, J. Fujita, and K. Saito, Bull. Chem. SOC.Jpn., 41, 359 (1968). (20) M. S. Wrighton, L. Pdungsap. and D. L. Morse, J. phys. Chem.. 79,66 (1975). (21) C.G. Hatchard and C. A. Parker, Proc. R. SOC.London. Ser. A, 235, 518 (1956). (22) E. E. Wegner and A. W. Adamson, J. Am. Chem. SOC.,88, 394 (1966).

/ Photosubstitution Reactivity of v ( C O ) 5 ( p y )Complexes